JPWO2008155908A1 - Wireless communication apparatus and symbol arrangement method - Google Patents

Abstract

A wireless communication apparatus capable of reducing the influence of CDD channel fluctuations of interference signals from other cells when using CDD. In this apparatus, an arrangement section (105) places some of the same symbols input from the repetition section (104) as subcarriers located at peak parts of CDD channel fluctuations of LD-CDD. At the same time, symbols other than the partial symbols are arranged on subcarriers located in valleys of the CD-D channel fluctuation of LD-CDD. Then, cyclic delay section (106-1) and cyclic delay section (106-2) transmit, for each symbol arranged in each of a plurality of subcarriers among signals input from arrangement section (105). Different cyclic delays are given according to the CDD mode input from the parameter control unit (101).

Description

  The present invention relates to a radio communication apparatus and a symbol arrangement method.

  In recent years, transmission techniques for realizing high-speed and large-capacity data transmission have been studied, and MIMO (Multi Input Multi Output) transmission techniques using a plurality of antennas have attracted attention. In MIMO transmission, it is possible to increase throughput by providing a plurality of antennas on both the transmission side and the reception side, preparing a plurality of propagation paths in the space between wireless transmission and reception, and spatially multiplexing each propagation path. it can.

  In addition, as a peripheral element technology for MIMO transmission, cyclic delay diversity that increases the selectivity of fading channels by equivalently increasing the number of delay paths by simultaneously transmitting signals with different cyclic delays for each antenna from a plurality of antennas. (CDD: Cyclic Delay Diversity) technology has been studied (for example, see Non-Patent Document 1). CDD has two types of CDD modes: SD-CDD (Small Delay CDD) with a small amount of cyclic delay and LD-CDD (Large Delay CDD) with a large amount of cyclic delay.

  In SD-CDD with a small amount of cyclic delay, fading channel fluctuations are slow over all resource blocks (RB). Therefore, with SD-CDD, a large frequency scheduling gain can be obtained, and the maximum multi-user diversity effect can be obtained. SD-CDD is a method suitable for data communication when a radio communication mobile station apparatus (hereinafter abbreviated as a mobile station) moves at low speed. On the other hand, in the LD-CDD having a large amount of cyclic delay, the fading channel fluctuation increases within 1 RB, so that a large frequency diversity gain can be obtained. LD-CDD is an effective method in situations where frequency scheduling transmission is difficult to apply.

As a peripheral element technology for MIMO transmission, there is a link adaptation technology. The link adaptation technique is a technique for adaptively controlling an MCS (Modulation and Coding Scheme) level indicating a coding rate and a modulation scheme according to the channel quality of a propagation path between transmission and reception. When link adaptation technology is applied to a mobile communication system, each mobile station measures SINR (Signal to Interference and Noise) of a common reference signal, and calculates an average SINR for each RB from the measured SINR. Each mobile station determines the MCS level used by the mobile station using the average SINR for each RB. Each mobile station reports the MCS level to a radio communication base station apparatus (hereinafter abbreviated as a base station). The base station encodes and modulates transmission data based on the MCS level from each mobile station and transmits it to each mobile station.
3GPP RAN WG1 LTE Adhoc meeting (2006.01) R1-060011 “Cyclic Shift Diversity for E-UTRA DL Control Channels & TP”

  As described above, the MCS level used by the mobile station is determined using the average SINR for each RB. Therefore, in order to appropriately use the determined MCS level for the plurality of subcarriers in the RB, it is preferable that all the SINRs of the plurality of subcarriers in the RB are the same as the average SINR. That is, it is preferable that the SINRs of the plurality of subcarriers in the RB are uniform. Therefore, the fading channel (hereinafter referred to as CDD channel) variation due to CDD is constant, and SD-CDD, which can obtain uniform SINR among subcarriers, is an effective method for link adaptation technology.

  However, when the CDD mode of the interference signal from another cell is LD-CDD, the interference power of each subcarrier varies with the CDD fluctuation period of LD-CDD. Therefore, when a desired signal is transmitted by SD-CDD from the base station, the SINR of each subcarrier in the RB fluctuates in the CDD channel fluctuation period of the LD-CDD from another cell in the mobile station. , There is a large difference in SINR between the subcarriers in the RB. Therefore, when the CDD mode of the interference signal from another cell is LD-CDD, appropriate link adaptation cannot be performed.

  Therefore, in the base station, in order to keep the SINR of a plurality of subcarriers in the RB uniform, it is necessary to reduce the influence of CDD channel fluctuations of interference signals from other cells.

  An object of the present invention is to provide a radio communication apparatus and a symbol arrangement method that can reduce the influence of CDD channel fluctuations of interference signals from other cells when CDD is used.

  The wireless communication apparatus of the present invention is a base station that performs cyclic delay diversity transmission of a multicarrier signal composed of a plurality of subcarriers, and in the plurality of subcarriers, a part of the same symbols is converted to LD- Arranged on the first subcarrier located in the peak portion of the channel fluctuation of CDD, and arranged symbols other than the part of the plurality of symbols on the second subcarrier located in the valley portion of the channel fluctuation. An arrangement is provided that includes arrangement means and transmission means for transmitting the multicarrier signal in which the plurality of symbols are arranged on the plurality of subcarriers.

  ADVANTAGE OF THE INVENTION According to this invention, when using CDD, the influence by the CDD channel fluctuation | variation of the interference signal from another cell can be reduced.

Block configuration diagram of a base station according to Embodiment 1 of the present invention The figure which shows the example of a change of MCS which concerns on Embodiment 1 of this invention. The figure which shows the processing flow of the transmission parameter control part which concerns on Embodiment 1 of this invention. The figure which shows the symbol arrangement | positioning which concerns on Embodiment 1 of this invention. Block configuration diagram of a mobile station according to Embodiment 1 of the present invention The figure which shows the symbol synthetic | combination process which concerns on Embodiment 1 of this invention. The figure which shows the symbol arrangement | positioning which concerns on Embodiment 2 of this invention. The figure which shows the symbol arrangement | positioning which concerns on Embodiment 2 of this invention. The block block diagram of the base station which concerns on Embodiment 2 of this invention Block configuration diagram of a mobile station according to Embodiment 2 of the present invention The figure which shows the symbol arrangement | positioning which concerns on Embodiment 2 of this invention (arrangement example 1: number N of cyclic delay shift samples) The figure which shows the symbol arrangement | positioning which concerns on Embodiment 2 of this invention (arrangement example 1: number N of cyclic delay shift samples) The figure which shows the symbol arrangement | positioning which concerns on Embodiment 2 of this invention (arrangement example 2: at the time of the 2nd transmission) The figure which shows the symbol arrangement | positioning which concerns on Embodiment 2 of this invention (arrangement example 2: at the time of the 3rd transmission) The figure which shows the symbol arrangement | positioning which concerns on Embodiment 2 of this invention (arrangement example 2: at the time of the 4th transmission)

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the following description, the wireless communication device on the transmission side is a base station, and the wireless communication device on the reception side is a mobile station. In the following description, the CDD mode of a desired signal transmitted from the base station is SD-CDD, and the CDD mode of an interference signal from another cell is LD-CDD.

(Embodiment 1)
The configuration of base station 100 according to the present embodiment is shown in FIG.

  In base station 100 shown in FIG. 1, transmission parameter control section 101, based on feedback information from the mobile station, MCS level (coding rate and modulation scheme), transmission data for transmission data (desired signal) to each mobile station. It controls the repetition factor (RF) and the CDD mode (SD-CDD or LD-CDD) of transmission data to each mobile station. Here, the feedback information from the mobile station includes the MCS level determined based on the SINR of the received signal of the mobile station, the CDD mode of transmission data to the mobile station, and the CDD mode of interference signals from other cells. . When the CDD mode of the interference signal from another cell is LD-CDD, transmission parameter control section 101 determines RF based on the number of cyclic delay shift samples of LD-CDD, that is, the CDD channel fluctuation period of LD-CDD. To do. In addition, the transmission parameter control unit 101 changes the MCS level to increase in accordance with the determined RF in order to prevent a decrease in data rate due to repetition. On the other hand, when the CDD mode of the interference signal from another cell is SD-CDD, the transmission parameter control unit 101 does not determine the RF and change the MCS level. Then, the transmission parameter control unit 101 generates a control signal indicating the MCS level after control, the determined RF, and the CDD mode of transmission data to the mobile station. Then, transmission parameter control section 101 outputs the controlled MCS level to encoding section 102 and modulation section 103, outputs the determined RF to repetition section 104, outputs the control signal to arrangement section 105, and moves it. The CDD mode of transmission data to the station is output to cyclic delay section 106-1 and cyclic delay section 106-2. Details of the control processing in the transmission parameter control unit 101 will be described later.

  Encoding section 102 encodes transmission data according to the coding rate input from transmission parameter control section 101. Then, encoding section 102 outputs the encoded transmission data to modulating section 103.

  Modulation section 103 modulates the encoded transmission data input from encoding section 102 according to the modulation scheme input from transmission parameter control section 101 to generate data symbols. Modulation section 103 then outputs the generated data symbol to repetition section 104.

  The repetition unit 104 repeats the data symbol input from the modulation unit 103 according to the RF input from the transmission parameter control unit 101. For example, when RF = 2, the repetition unit 104 repeats the data symbol to obtain the same two symbols. Then, repetition section 104 outputs the same plurality of symbols including data symbols and repetition symbols to arrangement section 105.

  Arrangement section 105 multiplexes the common reference signal, the control signal input from transmission parameter control section 101, and the same plurality of symbols input from repetition section 104, and also combines the multiplexed signal into a plurality of sub-signals. Place each on the carrier. At this time, arrangement section 105 arranges some of the same symbols on subcarriers located at the peak of the CDD channel fluctuation of LD-CDD, and arranges symbols other than the some of the symbols. It arrange | positions to the subcarrier located in the valley part of the CDD channel fluctuation | variation of LD-CDD. Arrangement unit 105 then outputs the multiplexed signal to cyclic delay unit 106-1 and cyclic delay unit 106-2. Details of the arrangement processing in the arrangement unit 105 will be described later.

  Cyclic delay section 106-1, IFFT (Inverse Fast Fourier Transform) section 107-1, CP adding section 108-1 and radio transmitting section 109-1 are provided corresponding to antenna 110-1. Further, cyclic delay section 106-2, IFFT section 107-2, CP adding section 108-2 and radio transmitting section 109-2 are provided corresponding to antenna 110-2.

  Cyclic delay unit 106-1 and cyclic delay unit 106-2, for each symbol arranged in a plurality of subcarriers among the multiplexed signals input from arrangement unit 105, are transmitted from transmission parameter control unit 101. Different cyclic delays are given according to the input CDD mode. Specifically, since the CDD mode input from transmission parameter control section 101 is SD-CDD, cyclic delay section 106-1 does not give a cyclic delay to each symbol, and cyclic delay section 106-2 , A cyclic delay of the number of SD-CDD cyclic delay shift samples is given to each symbol. Then, cyclic delay section 106-1 and cyclic delay section 106-2 output the signal after the cyclic delay to IFFT section 107-1 and IFFT section 107-2, respectively.

  IFFT section 107-1 and IFFT section 107-2 perform IFFT processing on the subcarriers on which the signals after cyclic delay input from cyclic delay section 106-1 and cyclic delay section 106-2 are arranged, respectively. The frequency domain signal is converted to a time domain signal to generate an OFDM symbol. Then, IFFT section 107-1 and IFFT section 107-2 output the OFDM symbols to CP adding section 108-1 and CP adding section 108-2, respectively.

  CP adding section 108-1 and CP adding section 108-2 add the same signal as the tail part of each OFDM symbol to the beginning of each OFDM symbol as a CP. Then, CP adding section 108-1 and CP adding section 108-2 output the OFDM symbols after the CP addition to radio transmitting section 109-1 and radio transmitting section 109-2, respectively.

  Radio transmitting sections 109-1 and 109-2 perform transmission processing such as D / A conversion, amplification and up-conversion on the OFDM symbol after CP addition, and transmit the OFDM symbol after transmission processing to antennas 110-1 and 110-2. -2 at the same time. Thereby, a plurality of OFDM symbols are CDD transmitted from a plurality of antennas.

  Next, details of the control processing in the transmission parameter control unit 101 will be described.

  Transmission parameter control section 101 determines RF based on the number of LD-CDD cyclic delay shift samples of interference signals from other cells. Specifically, transmission parameter control section 101 sets RF as the number of subcarriers corresponding to a frequency interval for one period of CDD channel fluctuation of LD-CDD. For example, when the number of cyclic delay shift samples is N / 2, the number of subcarriers corresponding to the frequency interval for one period of the CDD channel fluctuation of LD-CDD is 2, so the transmission parameter control unit 101 sets RF to 2 decide. Similarly, transmission parameter control section 101, when the number of cyclic delay shift samples is N / 4 (that is, when the number of subcarriers corresponding to the frequency interval for one period of CDD channel fluctuation of LD-CDD is 4), When RF is determined to be 4 and the number of cyclic delay shift samples is N / 8 (that is, when the number of subcarriers corresponding to the frequency interval of one period of CDD channel fluctuation of LD-CDD is 8), RF is set to 8 To decide. Here, N is the number of FFT (Fast Fourier Transform) points. Further, when the CDD mode of the interference signal from another cell is SD-CDD, the transmission parameter control unit 101 does not set the RF.

  Next, transmission parameter control section 101 increases the MCS level included in the feedback information according to the determined RF, that is, the number of subcarriers corresponding to the frequency interval for one period of LDD-CDD CDD channel fluctuation. Here, when the transmission data is repeated at RF = 2, two identical symbols are obtained, so that the data rate is reduced to ½. Therefore, the transmission parameter control unit 101 prevents the data rate from being lowered during data transmission by changing the MCS level to double the data rate.

  For example, as shown in FIG. 2, when the RF determined by the transmission parameter control unit 101 is 2, and the MCS level included in the feedback information is R = 1/3, QPSK, the transmission parameter control unit 101 The conversion rate is changed to 2/3, or the modulation method is changed to 16QAM. That is, the transmission parameter control unit 101 changes the MCS level to R = 2/3, QPSK, or R = 1/3, 16QAM. Here, the data rate in the case of R = 2/3 and QPSK and the data rate in the case of R = 1/3 and 16QAM are both twice the data rate in the case of R = 1/3 and QPSK. As described above, when the transmission data is repeated at RF = 2, the data rate is changed to the MCS level that is doubled, so that it is possible to prevent the data rate from being lowered during data transmission. As shown in FIG. 2, the transmission parameter control unit 101 may change either the coding rate or the modulation scheme when increasing the MCS level according to RF. Both may be changed.

  Next, the parameter change processing flow of the transmission parameter control unit 101 will be described with reference to the flowchart of FIG.

  In ST (step) 101, transmission parameter control section 101, when the CDD mode (other cell CDD mode) of the interference signal from another cell is LD-CDD (ST101: YES), from ST102, RF is determined based on the number of cyclic delay shift samples of LD-CDD of the interference signal.

  In ST103, transmission parameter control section 101 changes the MCS level based on the RF determined in ST102.

  On the other hand, when the CDD mode of the interference signal from another cell is SD-CDD (ST101: NO), transmission parameter control section 101 does not perform repetition on the data symbol in base station 100, so nothing is done. The process ends without doing.

  Next, details of the data symbol arrangement processing in arrangement section 105 will be described. Here, RF determined by transmission parameter control section 101 is set to 2, and the number of cyclic delay shift samples of LD-CDD of interference signals from other cells is set to N / 2.

FIG. 4 shows an RB composed of ₁₂ subcarriers f _{1 to} f ₁₂ . Here, since RF is 2, as shown in FIG. 4, as shown in FIG. 4, data symbols S1 to S6 and repetition symbols S1 ′ to S6 ′ generated by repeating each of S1 to S6 are displayed in placement section 105. Are input from the repetition unit 104. Here, S1 to S6 and S1 ′ to S6 ′ are the same symbols.

Further, since the number of cyclic delay shift samples of LD-CDD of interference signals from other cells is N / 2, as shown in FIG. The number of subcarriers for one period (variation in interference power) is 2. In other words, the frequency interval between the subcarriers in subcarriers f _{1 to} f ₁₂ is a half period of CDD channel fluctuation of LD-CDD of interference signals from other cells. That is, the CDD channels of LD-CDD in adjacent subcarriers have opposite phases. For example, as shown in FIG. 4, _{f 1} is LD-CDD of located on a mountain portion (high interference power) of the CDD channel fluctuation, _{f 2} adjacent to _{f 1} valley portion of the CDD channel fluctuation of LD-CDD ( (Small interference power).

  Therefore, arranging section 105 places the same plurality of symbols in sub-carriers located in the peak portion (large interference power) of CDD channel fluctuation of LD-CDD and in the valley portion (small interference power) of CDD channel fluctuation of LD-CDD. It arrange | positions equally to the subcarrier located. Here, since RF = 2, allocating section 105 uses the same two symbols as the subcarriers located at the peak portion (large interference power) of CDD channel fluctuation of LD-CDD and the CDD channel fluctuation of LD-CDD. One for each subcarrier located in the valley portion (small interference power).

Specifically, as shown in FIG. 4, placement section 105 places S1 on f ₁ (the peak portion of the CDD channel fluctuation of LD-CDD) and S1 ′ on f ₂ (the CDD channel of LD-CDD). Place in the valley of fluctuation). That is, S1 and S1 ′ are respectively arranged in f ₁ and f ₂ that are in opposite phases in the CDD channel of the LD-CDD. Similarly, placement section 105 places S2 at f ₃ (the peak portion of the CDD channel fluctuation of LD-CDD) and S2 ′ at f ₄ (the valley portion of the CDD channel fluctuation of LD-CDD). The same applies to S3 to S6 and S3 ′ to S6 ′.

  As described above, the same plurality of symbols include a peak portion of the CDD channel fluctuation of LD-CDD (large interference power), that is, a subcarrier having poor channel quality (low SINR) and a CDD channel fluctuation of LD-CDD. It is distributed and arranged in valley portions (small interference power), that is, subcarriers with good channel quality (high SINR). In other words, since the same plurality of symbols are uniformly distributed over a plurality of subcarriers corresponding to a frequency interval of one period of CDD channel fluctuation of LD-CDD, a diversity effect can be obtained. Thereby, the interference power from other cells is averaged in a plurality of subcarriers in the RB in which the data symbols are arranged, and the interference power can be made uniform.

  Next, FIG. 5 shows the configuration of mobile station 200 according to the present embodiment.

  In mobile station 200 shown in FIG. 5, radio receiving section 202-1, CP removing section 203-1 and FFT section 204-1 are provided corresponding to antenna 201-1. Radio reception section 202-2, CP removal section 203-2, and FFT section 204-2 are provided corresponding to antenna 201-2.

  Radio receiving section 202-1 and radio receiving section 202-2 receive OFDM symbols, which are multicarrier signals that are CDD transmitted from base station 100 (FIG. 1), via antenna 201-1 and antenna 201-2, respectively. The OFDM symbol is subjected to reception processing such as down-conversion and A / D conversion. Then, radio reception section 202-1 and radio reception section 202-2 output the OFDM symbols after radio reception processing to CP removal section 203-1 and CP removal section 203-2, respectively. The OFDM symbol includes a plurality of identical symbols including a data symbol and a repetition symbol, a common reference signal, and a control signal. Further, this OFDM symbol is interfered by a signal from another cell in the propagation path.

  CP removing section 203-1 and CP removing section 203-2 remove the CP from the OFDM symbols input from radio receiving section 202-1 and radio receiving section 202-2, respectively. Then, CP removal section 203-1 and CP removal section 203-2 output the OFDM symbols after CP removal to FFT section 204-1 and FFT section 204-2, respectively.

  FFT section 204-1 and FFT section 204-2 perform FFT processing on the OFDM symbols respectively input from CP removal section 203-1 and CP removal section 203-2, and convert the time domain signal to the frequency domain signal. Convert to Then, FFT section 204-1 and FFT section 204-2 output the signal after the FFT to separation section 205.

  Separating section 205 separates the signal after FFT input from FFT section 204-1 and FFT section 204-2 into the same plurality of symbols, common reference signal, and control signal. Separating section 205 then outputs the same plurality of symbols to combining section 206, outputs a common reference signal to SINR measuring section 209, and controls signals to combining section 206, demodulating section 207, decoding section 208, and SINR measuring section. To 209.

  The combining unit 206 combines a data symbol and a repetition symbol corresponding to the data symbol among the same plurality of symbols input from the separating unit 205 to generate a combined symbol. Specifically, combining section 206 is arranged in a symbol arranged in a subcarrier located in a peak portion of CDD channel fluctuation of LD-CDD and a subcarrier located in a valley portion of CDD channel fluctuation of LD-CDD. Combining with the symbol. Here, the synthesis unit 206 determines the number of symbols to be synthesized according to the RF indicated by the control signal input from the separation unit 205. Then, combining section 206 outputs the generated combined symbol to demodulation section 207. Details of the composition processing in the composition unit 206 will be described later.

  Demodulating section 207 demodulates the combined symbol input from combining section 206 according to the modulation scheme indicated by the control signal input from separating section 205. Demodulation section 207 then outputs the demodulated data signal to decoding section 208.

  Decoding section 208 decodes the demodulated data signal input from demodulation section 207 according to the coding rate indicated by the control signal input from separation section 205. Decoding section 208 then outputs the decoded data signal as received data.

  On the other hand, the SINR measurement unit 209 measures the SINR of the common reference signal input from the separation unit 205 based on the CDD mode indicated by the control signal input from the separation unit 205. Specifically, the SINR measurement unit 209 gives a cyclic delay in the CDD mode indicated by the control signal to the common reference signal, and measures the SINR of the common reference signal after the cyclic delay. As described above, the SINR measurement unit 209 can reflect the influence of the CDD channel of the data signal on the SINR measurement of the common reference signal by giving the common reference signal the same cyclic delay as that of the data signal. Then, the SINR measurement unit 209 outputs the measured SINR to the transmission parameter determination unit 210.

  Transmission parameter determination section 210 determines the MCS level and the CDD mode of transmission data addressed to the own station based on the SINR input from SINR measurement section 209. For example, the transmission parameter determination unit 210 determines a larger MCS as the SINR is higher. Further, for example, when the SINR is equal to or greater than the threshold, the transmission parameter determination unit 210 determines the CDD mode of the transmission data addressed to the own station to the SD-CDD mode, and when the SINR is less than the threshold, the CDD mode of the transmission data addressed to the own station. To the LD-CDD mode. Then, transmission parameter determination section 210 outputs MCS level, CDD mode of transmission data addressed to its own station, and CDD mode of interference signals from other cells input from a reception section (not shown) to feedback information generation section 211.

  The feedback information generation unit 211 generates feedback information including the MCS level input from the transmission parameter determination unit 210, the CDD mode of transmission data addressed to the own station, and the CDD mode of interference signals from other cells. Then, the feedback information generation unit 211 feeds back the generated feedback information to the base station 100.

  Next, details of the composition processing in the composition unit 206 will be described.

FIG. 6 shows an RB composed of ₁₂ subcarriers f _{1 to} f ₁₂ as in FIG. Here, RF indicated by the control signal is set to 2. Further, as described above, the same symbol is arranged in adjacent subcarriers. Further, in the received signal before symbol synthesis, the frequency interval for one period of the CDD channel fluctuation (interference power) of the LD-CDD of the interference signal from another cell is equivalent to the frequency interval of 2 subcarriers as in FIG. To do. Therefore, the CDD channel fluctuation (interference power) of LD-CDD has an opposite phase between adjacent subcarriers. That is, every other subcarrier, high interference power (the peak portion of the LD-CDD CDD channel fluctuation) and small interference power (the LD-CDD valley portion of the CDD channel fluctuation) appear alternately. Here, as shown in FIG. 6A, the interference power of the interference signal from another cell is large in the odd-numbered subcarrier (the peak portion of the CDD channel fluctuation of LD-CDD), and the even-numbered subcarrier is small. Assume that this is the valley portion of the CDD channel fluctuation of LD-CDD. On the other hand, as shown in FIG. 6A, the reception power of a signal from base station 100 (FIG. 1), that is, the desired power of transmission data transmitted by SD-CDD is constant between subcarriers. Therefore, the SINR in each subcarrier before symbol combination varies according to the variation in interference power from other cells. That is, as shown in FIG. 6B, the SINR of odd-numbered subcarriers is low, and the SINR of even-numbered subcarriers is high.

Since RF = 2, the synthesis unit 206 performs symbol synthesis on the symbols arranged on the adjacent two subcarriers. Specifically, as shown in FIG. 6C, combining section 206 performs data symbols S1 and f ₂ (LD-CDD CDD channel fluctuation fluctuations) arranged at f ₁ (the peak part of LD-CDD CDD channel fluctuations). The repetition symbol S1 ′ arranged in the valley portion) is symbol-synthesized to generate a synthesized symbol S1 ″. Similarly, the synthesis unit 206 is arranged in f ₃ (the peak portion of the CDD channel fluctuation of LD-CDD). S2 ″ is generated by combining symbols S2 and S2 ′ arranged in f ₄ (the valley portion of the CDD channel fluctuation of LD-CDD). The same is true for f ₅ ~f _12.

Here, as shown in FIG. 6C, the received power at f ₁ and f ₂ where S1 ″ is arranged is the received power at f ₁ where S1 is arranged and the received power of f ₂ where S1 ′ is arranged. Therefore, the SINR at f ₁ and f ₂ where S1 ″ is arranged is equal to the average value of the SINR of f _{1 and} the SINR of f ₂ as shown in the SINR characteristics after symbol synthesis in FIG. Become. The same applies to S2 ″ to S6 ″. That is, as shown in FIG. 6D, since the SINRs of the received signals after the symbol synthesis of all subcarriers are averaged, the SINR of each subcarrier of transmission data transmitted by SD-CDD is a CDD channel of LD-CDD. It is possible to prevent fluctuations in the same way as fluctuations.

  As described above, according to the present embodiment, a plurality of identical symbols generated by repetition of transmission data are generated from the peak portion of CDD channel fluctuation (from the own cell) due to LD-CDD of interference signals from other cells. Subcarriers located in the portion where the SINR of the desired signal is low) and subcarriers located in the valley portion of the CDD channel fluctuation due to LD-CDD of the interference signal from other cells (the portion where the SINR of the desired signal from the own cell is high) Distributed to the carrier. Thereby, as described above, the SINRs of all subcarriers in the RB can be made uniform, and can be approximated to the CDD channel of SD-CDD. That is, according to the present embodiment, even when transmission data is transmitted by SD-CDD, it is possible to reduce the influence due to the CDD channel fluctuation of LD-CDD of interference signals from other cells. Thereby, even when transmission data is transmitted by SD-CDD, since the SINR of all subcarriers in the RB can be made uniform in the mobile station, the accuracy of link adaptation performed in units of RBs is improved. Can do.

In the present embodiment, as shown in FIG. 4, data symbols and repetition symbols generated by repetition of the data symbols are arranged on consecutive subcarriers. However, the data symbol and the repetition symbol do not need to be allocated to consecutive subcarriers, respectively, and are allocated to subcarriers located at peak portions and valley portions of LD-CDD CDD channel fluctuations, respectively. It only has to be done. For example, in FIG. 4, a data symbol and a repetition symbol are in any one of subcarriers f ₁ , f ₃ , f ₅ , f ₇ , f ₉ , and f ₁₁ located at the peak portion of the CDD channel fluctuation of LD-CDD. One of the subcarriers f ₂ , f ₄ , f ₆ , f ₈ , f ₁₀ , and f ₁₂ located in the valley portion of the CDD channel fluctuation of the LD-CDD may be arranged. .

(Embodiment 2)
In the first embodiment, the same plurality of data symbols are arranged in either the peak portion or valley portion of the CD-D channel fluctuation of LD-CDD without considering the time. That is, a plurality of identical data symbols are combined at the same time.

  However, if the same plurality of data symbols are arranged on both the subcarrier located in the peak part of the CDD channel fluctuation of LD-CDD and the subcarrier located in the valley part, the same effect as in the first embodiment is obtained. be able to. That is, the same plurality of data symbols may not be arranged on subcarriers at the same time. That is, the same plurality of data symbols may be arranged in both the peak portion and the valley portion of the CDD channel variation of LD-CDD at different times. Therefore, in the present embodiment, the same plurality of data symbols are arranged at different times on the subcarriers located in the peak portion of the LD-CDD CDD channel fluctuation and the subcarriers located in the valley portion.

  First, base station 100 (FIG. 1) according to the present embodiment will be described. In base station 100 according to the present embodiment, description of the same operation as in Embodiment 1 is omitted.

  Transmission parameter control section 101 holds a plurality of subcarrier arrangement patterns for data symbols. Then, the transmission parameter control unit 101 determines one of a plurality of arrangement patterns according to the number of transmission data transmissions. Note that the number of transmissions is the same as the number of RFs determined by the transmission parameter control unit 101. Then, transmission parameter control section 101 outputs the determined arrangement pattern to arrangement section 105.

  The repetition unit 104 outputs the data symbols input from the modulation unit 103 to the placement unit 105 by the same number of transmissions as the RF input from the transmission parameter control unit 101 at different times. The repetition unit 104 may duplicate the data symbols as many times as the number of transmissions to generate the same plurality of data symbols, and output the generated plurality of the same data symbols to the arrangement unit 105 at different times, respectively. The data symbols may be temporarily stored, and the stored data symbols may be output to the arrangement unit 105 at different times. The data symbols are duplicated at each transmission to generate a plurality of identical data symbols. The same plurality of data symbols may be output to the arrangement unit 105 at different times.

  Arrangement section 105 arranges the same plurality of data symbols input at different times from repetition section 104 according to the arrangement pattern input from transmission parameter control section 101 on each subcarrier.

  Next, details of the arrangement processing in the arrangement unit 105 will be described.

FIG. 7 shows an RB composed of ₁₂ subcarriers f _{1 to} f ₁₂ . Here, as in the first embodiment, out of f _{1 to} f ₁₂ , odd-numbered subcarriers are located in the peak portion (large interference power) of the CDD channel fluctuation of LD-CDD of interference signals from other cells. The even-numbered subcarriers are assumed to be located in the valley portion (small interference power) of the CDD channel fluctuation of the LD-CDD of the interference signal from another cell. In addition, data symbols S <b> 1 to S <b> 12 are input to the placement unit 105 from the repetition unit 104 at different times. Also, RF is 2. That is, S1 to S12 are input to the placement unit 105 twice.

  Arrangement section 105 arranges data symbols arranged in subcarriers located in the peak portion of CDD channel fluctuation of LD-CDD (valley portion of CDD channel fluctuation of LD-CDD) in the first transmission into LD in the second transmission. -It arrange | positions to the subcarrier located in the valley part (CDD channel fluctuation peak part of LD-CDD) of the CDD channel fluctuation of CDD.

Specifically, arranging section 105, in the first transmission, as shown in FIG. _7, placing the S1~S12 to f 1 _{~f 12} respectively. That, S1, S3, S5, S7 , S9, S11 is the _{f 1, f 3, f 5} , f 7, f 9, f 11 is located in the mountain portion (high interference power) of the CDD channel fluctuation of LD-CDD F ₂ , f ₄ , f ₆ , f ₈ , f ₁₀ where S 2, S 4, S 6, S 8, S 10, S 12 are located in the valley part (small interference power) of the CDD channel fluctuation of LD-CDD. , respectively disposed _{f 12.}

Then, in the second transmission, as shown in FIG. 7, arrangement section 105 has S2, S4, S6, S8, S10, and S12 located at the peak portion (large interference power) of CDD channel fluctuation of LD-CDD. f ₁ , f ₃ , f ₅ , f ₇ , f ₉ , and f ₁₁ are arranged respectively, and S 1, S 3, S 5, S 7, S 9, and S 11 are valley portions of CDD channel fluctuations of LD-CDD (small interference power) ) Located at f ₂ , f ₄ , f ₆ , f ₈ , f ₁₀ , and f ₁₂ .

  Thus, at different times (at the time of the first transmission and at the time of the second transmission), the same plurality of data symbols are arranged in the peak and valley portions of the LD-CDD CDD channel fluctuation as in the first embodiment. can do.

  Next, mobile station 200 (FIG. 5) according to the present embodiment will be described. In mobile station 200 according to the present embodiment, description of the same operation as in Embodiment 1 is omitted.

  When receiving the first transmission data, combining section 206 stores the data symbol input from demultiplexing section 205 and outputs it as it is to demodulation section 207. On the other hand, at the time of receiving the second transmission data, the combining unit 206 generates a combined symbol by combining the data symbol input from the separating unit 205 and the stored data symbol, and stores the generated combined symbol. Output to demodulator 207. Here, the combining unit 206 holds the same arrangement pattern as the plurality of arrangement patterns held by the transmission parameter control unit 101 of the base station 100 (FIG. 1). Further, the synthesis unit 206 determines the arrangement pattern to be used in the plurality of arrangement patterns based on the RF indicated in the control information input from the separation unit 205.

  Next, details of the composition processing in the composition unit 206 will be described.

FIG. 8 shows an RB composed of ₁₂ subcarriers f _{1 to} f ₁₂ as in FIG. Here, every other subcarrier, high interference power (the peak portion of LD-CDD CDD channel fluctuation) and small interference power (the LD-CDD valley portion of CDD channel fluctuation) appear alternately. Further, when receiving the first transmission data, that is, the first transmission data shown in FIG. 7, the subcarrier f located at the peak portion (large interference power) of the CDD channel fluctuation of LD-CDD as shown in FIG. 8A. ₁ , f ₃ , f ₅ , f ₇ , f _9, f ₁₁ , data symbols S 1, S 3, S 5, S 7, S 9, S 11 are arranged in the valley portion (small interference power) of the CDD channel fluctuation of LD-CDD. subcarriers _{f 2,} f ₄ which is _{located, f 6, f 8, f} 10, f 12 in S2, S4, S6, S8, S10, S12 are arranged. That is, as shown in FIG. 8B, the SINR of odd-numbered subcarriers is low, and the SINR of even-numbered subcarriers is high.

Further, when receiving the second transmission data, that is, the second transmission data shown in FIG. 7, the subcarrier f located at the peak portion (large interference power) of the CDD channel fluctuation of LD-CDD as shown in FIG. 8C. ₁ , f ₃ , f ₅ , f ₇ , f _9, f ₁₁ are arranged S 2, S 4, S 6, S 8, S 10, S 12, and located in the valley portion (small interference power) of CDD channel fluctuation of LD-CDD. subcarriers _{f 2, f 4, f 6} , f 8, f 10, f 12 in S1, S3, S5, S7, S9, S11 are arranged. That is, as shown in FIG. 8D, the SINR of odd-numbered subcarriers is low, and the SINR of even-numbered subcarriers is high.

Combining section 206 receives the data symbol arranged on the subcarrier located at the peak portion of the LD-CDD CDD channel fluctuation (the valley portion of the LD-CDD CDD channel fluctuation) at the time of receiving the first transmission data, and the second time At the time of reception of transmission data, the data symbols arranged on the subcarriers located in the valley part of the CDD channel fluctuation of LD-CDD (the peak part of CDD channel fluctuation of LD-CDD) are combined. Specifically, as illustrated in FIG. 8E, the combining unit 206 includes S1 arranged in f _{1 of the} first transmission data (the peak portion of the CDD channel fluctuation of LD-CDD) and f _{2 of the} second transmission data ( S1 arranged in the valley portion of the CDD channel fluctuation of LD-CDD) is combined to generate a combined symbol S1 ′. Similarly, combining section 206 has S2 arranged in f _{2 of the} first transmission data (the valley portion of the CDD channel fluctuation of LD-CDD) and f _{1 of the} second transmission data (the peak of the CDD channel fluctuation of LD-CDD). S2 arranged in (part) is synthesized to generate a synthesized symbol S2 ′. The same applies to the S3~S12 disposed f ₃ ~f _12. As a result, the synthesis unit 206 generates synthesized symbols S1 ′ to S12 ′.

  That is, combining section 206 has subcarriers located at the peak of the CDD channel fluctuation of LD-CDD in the first transmission data (second transmission data), that is, data symbols arranged on subcarriers with low SINR, and 2 In the first transmission data (first transmission data), subcarriers located in valley portions of the CDD channel fluctuation of LD-CDD, that is, data symbols arranged on subcarriers having a high SINR are combined. Thereby, combining section 206 can supplement the SINR of the data symbol having a low SINR in the first transmission data (second transmission data) with the second transmission data. Therefore, since the SINRs between the combined symbols obtained in the mobile station are averaged to the same level, similarly to Embodiment 1, the influence of the CD-D channel variation of LD-CDD on the transmission data transmitted by SD-CDD Can be reduced.

  Thus, the same effect as in the first embodiment can be obtained even if the same data symbols are arranged in the peak and valley portions of the CD-D channel fluctuation of LD-CDD at different times.

  As a technique for transmitting the same data at different times, there is a CC (Chase Combining) type HARQ (Hybrid Automatic Repeat reQuest). In CC-type HARQ, the mobile station feeds back an ACK (Acknowledgment) signal to the base station as a response signal when there is no error in the received data and a NACK (Negative Acknowledgment) signal when there is an error. When receiving the NACK signal, the base station retransmits all of the transmission data. Then, the mobile station combines the data retransmitted from the base station and the data with errors received in the past, and performs error correction decoding on the combined data.

  Then, next, the case where this Embodiment is applied to CC system HARQ is demonstrated as an example.

  First, the base station according to this example will be described. FIG. 9 shows the configuration of base station 300 according to this example. In FIG. 9, the same components as those shown in FIG. Further, the description of the same operation as that described above is also omitted.

  In base station 300 shown in FIG. 9, transmission parameter control section 101 calculates the number of retransmissions from the response signal included in the feedback information, and determines the subcarrier arrangement pattern for the data symbol based on the number of retransmissions. Then, transmission parameter control section 101 outputs the determined arrangement pattern to arrangement section 105. Also, the transmission parameter control unit 101 outputs a response signal to the HARQ unit 301.

  HARQ section 301 stores the data symbol input from modulation section 103 and outputs the data symbol to arrangement section 105 according to the response signal input from transmission parameter control section 101. Specifically, HARQ section 301 outputs a data symbol to arrangement section 105 in the first transmission (initial transmission). HARQ section 301 outputs the stored data symbol to arrangement section 105 when a NACK signal is input from transmission parameter control section 101, that is, in the second transmission (first retransmission). Further, when an ACK signal is input from transmission parameter control section 101, HARQ section 301 stops outputting data symbols to arrangement section 105 and discards the stored data symbols.

  Next, the mobile station according to this example will be described. FIG. 10 shows the configuration of the mobile station 400 according to this example. In FIG. 10, the same components as those shown in FIG. Further, the description of the same operation as that described above is also omitted.

  In mobile station 400 shown in FIG. 10, combining section 401 stores the data symbol input from demultiplexing section 205 and outputs it to demodulation section 207 as it is when receiving the first transmission data (initial transmission data). On the other hand, when receiving the second transmission data (first retransmission data), that is, when a NACK signal is input from an error detection unit 402 described later, the combining unit 401 receives data input from the separation unit 205. The symbol and the stored data symbol are combined to generate a combined symbol, and the generated combined symbol is stored and output to the demodulation unit 207. Further, when the ACK signal is input from the error detection unit 402, the synthesis unit 401 discards the stored data symbol.

  The error detection unit 402 performs error detection on the decoded data signal input from the decoding unit 208. If there is an error in the decoded data signal as a result of error detection, error detection section 402 generates a NACK signal as a response signal and outputs it to combining section 401 and feedback information generation section 211. If there is no error, an ACK signal is generated as a response signal and output to the combining unit 401 and the feedback information generating unit 211. In addition, error detection section 402 outputs the decoded data signal as received data when there is no error in the decoded data signal.

  The feedback information generation unit 211 uses the response signal input from the error detection unit 402 to generate feedback information.

  In the present embodiment, the base station transmits the same plurality of data symbols at different times with the number of RF transmissions. On the other hand, in CC-based HARQ, the base station transmits the same data symbol at different times when a NACK signal is fed back as a response signal, that is, when retransmission processing occurs. That is, in the CC-type HARQ, the same effect as in the present embodiment can be obtained when retransmission processing occurs.

  However, in the HARQ of the CC scheme, the retransmission process may be completed with the same number of RFs, that is, the number of retransmissions less than the number of subcarriers corresponding to the frequency interval for one period of CDD channel fluctuation of LD-CDD. That is, in the CC scheme HARQ, it may be impossible to arrange the same data symbol on all subcarriers among subcarriers corresponding to the frequency interval for one period of CDD channel fluctuation of LD-CDD.

  Therefore, at the time of the second transmission (at the time of the first retransmission), placement section 105 has a subcarrier corresponding to a frequency interval corresponding to a half cycle of the CDD channel fluctuation period of LD-CDD at the time of the first transmission (at the first transmission). Data symbols arranged apart from each other are exchanged with each other. Here, the interference powers in the subcarriers separated by a half period of the CDD channel fluctuation period of LD-CDD are in an opposite phase relationship. By combining the data symbol arranged on the subcarrier at the first transmission (at the first transmission) and the data symbol arranged on the subcarrier at the second transmission (at the first retransmission), LD− Of the subcarriers corresponding to the frequency interval for one period of CDD channel fluctuation of CDD, the SINR of two subcarriers can be averaged reliably.

For example, in the case of RF = 2, that is, when the number of subcarriers corresponding to the frequency interval for one period of CDD channel fluctuation of LD-CDD is 2, the arrangement unit 105 performs the first transmission shown in FIG. Data symbols separated by one subcarrier, that is, data symbols arranged on adjacent subcarriers are exchanged with each other. Specifically, the arrangement unit 105, interchanging the S2, which are arranged in _{f 2} adjacent to S1 and _{f 1} which are located in _{f 1,} to place the _{f 1} to S2, placing the _{f 2} to S1. Similarly, arranging section 105, switches the S4, disposed _{f 4} adjacent to S3 and the _{f 3} disposed _{f 3,} arranged _{f 3} to S4, placing the _{f 4} to S3. The same applies to the S5~S12 disposed f ₅ ~f _12. Thus, the arrangement pattern at the second transmission (at the first retransmission) is the same as the arrangement pattern at the second transmission shown in FIG. That is, the symbol composition shown in FIG. 8 can be performed.

  In this way, at the time of retransmission, data symbols are arranged on subcarriers corresponding to the reverse phase of the CDD channel fluctuation of LD-CDD with respect to the subcarriers arranged at the first transmission (at the first transmission). As a result, even when a data symbol is arranged on the subcarrier with the worst SINR at the first transmission, the data symbol can be arranged on the subcarrier with the best SINR at the second transmission (at the first retransmission). it can. Therefore, even when the number of retransmissions is smaller than RF, it is possible to obtain the maximum effect of reducing the influence due to the CDD channel fluctuation of LD-CDD.

  In this example, the case where the number of cyclic delay shift samples is N / 2 has been described as shown in FIG. However, when the number of cyclic delay shift samples is N / 3, that is, when the number of subcarriers corresponding to the frequency interval for one period of the CDD channel fluctuation of LD-CDD is 3, as shown in FIG. At the time of transmission (at the time of the first retransmission), data symbols separated by two subcarriers are exchanged. Also, when the number of cyclic delay shift samples is N / 4, that is, when the number of subcarriers corresponding to the frequency interval for one period of CDD channel fluctuation of LD-CDD is 4, the second transmission (the first retransmission) ), The data symbols separated by 3 subcarriers are exchanged as shown in FIG. 11B.

  Further, in this example, the description has been made up to the second transmission (first retransmission). However, even after the third transmission, it is possible to return to the arrangement pattern at the first transmission again and use the arrangement pattern at the first transmission and the arrangement pattern at the second transmission alternately.

  The case where the present embodiment is applied to CC-type HARQ has been described above.

  Thus, according to the present embodiment, in the transmission data, the base station transmits data symbols arranged in subcarriers having low SINR (high SINR) in the first transmission to high SINR (low in the second transmission). SINR) subcarriers. As a result, the mobile station can improve the SINR of the data symbols arranged in the low SINR subcarriers when receiving the first transmission data when receiving the second transmission data. For this reason, the SINRs of the entire data symbols can be averaged to be uniform. That is, according to the present embodiment, similarly to Embodiment 1, even when CDD is used, it is possible to reduce the influence of CDD channel fluctuations of interference signals from other cells.

  In the present embodiment, for example, as shown in FIGS. 12A, 12B, and 12C, an arrangement pattern in which data symbols are shifted by one subcarrier for each transmission count may be used. Specifically, with respect to the arrangement pattern of the data symbols at the first transmission shown in FIG. 7, the arrangement pattern at the second transmission shifts the data symbols by one subcarrier as shown in FIG. 12A. In the arrangement pattern at the time of transmission, as shown in FIG. 12B, the data symbol is shifted by 2 subcarriers, and in the arrangement pattern at the time of the fourth transmission, the data symbol is shifted by 3 subcarriers as shown in FIG. 12C. As a result, when data symbols are transmitted as many times as the number of transmissions as RF, data symbols are arranged on all subcarriers of a plurality of subcarriers corresponding to the frequency interval for one period of CDD channel fluctuation of LD-CDD. The same actions and effects as described above can be achieved.

  Also, when the present embodiment is applied to CC-type HARQ, the arrangement pattern shown in FIGS. 12A, 12B, and 12C may be used. Specifically, the number of cyclic delay shift samples of LD-CDD at the second transmission (at the first retransmission) with respect to the data symbol arrangement pattern at the first transmission (at the first transmission) shown in FIG. Is N / 2, the arrangement pattern shown in FIG. 12A is used, and when the number of LD-CDD cyclic delay shift samples is N / 3, the arrangement pattern shown in FIG. When the number of samples is N / 4, the arrangement pattern shown in FIG. 12C may be used.

  Furthermore, when this embodiment is applied to CC-type HARQ, the arrangement patterns shown in FIGS. 12A, 12B, and 12C may be used according to the number of retransmissions. Specifically, when the number of cyclic delay shift samples of LD-CDD is N / 2 with respect to the data symbol arrangement pattern at the first transmission (first transmission) shown in FIG. 7, at the second transmission (1 In the second retransmission), the arrangement pattern shown in FIG. 12A is used. When the number of cyclic delay shift samples in LD-CDD is N / 3, the arrangement pattern shown in FIG. 12B is used at the third transmission (at the second retransmission) in addition to the arrangement pattern at the first and second transmissions. . When the number of cyclic delay shift samples of LD-CDD is N / 4, in addition to the arrangement pattern at the time of the first to third transmissions, at the time of the fourth transmission (at the time of the third retransmission), the arrangement pattern shown in FIG. Is used. Thereby, as the number of retransmissions increases, the number of subcarriers in which the same data symbol is arranged increases, and transmissions corresponding to a plurality of subcarriers corresponding to a frequency interval for one period of CDD channel fluctuation of LD-CDD. The same effect as this embodiment can be obtained by the number of times.

  The embodiments of the present invention have been described above.

  In the above embodiment, the receiving unit (not shown) of the mobile station receives the CDD mode of the interference signal from another cell and feeds it back to the base station. However, in the present invention, the CDD mode of the interference signal from another cell is determined at each mobile station using the received signal, and the determined CDD mode of the interference signal from the other cell is fed back to the base station. May be. Moreover, you may notify between base stations via a radio network controller (RNC: Radio Network Controller), without feeding back to a base station via a mobile station.

  CDD may be referred to as CSD (Cyclic Shift Diversity). The CP is sometimes referred to as a guard interval (GI). In addition, the subcarrier may be referred to as a tone. Further, the base station may be represented as Node B, and the mobile station may be represented as UE.

  In the above embodiment, SINR is estimated as channel quality, but SNR, SIR, CINR, CNR, CIR, received power, interference power, bit error rate, packet error rate, throughput, and predetermined error rate can be achieved. You may estimate MCS, the moving speed of a mobile station, delay spread, etc. as channel quality.

  For example, when estimating the moving speed of the mobile station as the channel quality, the mobile station 200 (FIG. 5) includes a moving speed measuring unit instead of the SINR measuring unit 209, and the moving speed measuring unit measures the moving speed of the mobile station 200. To do. Then, transmission parameter determining section 210 (FIG. 5) of mobile station 200 determines that the CDD mode of transmission data addressed to the mobile station 200 is the LD-CDD mode when the moving speed of mobile station 200 is equal to or higher than the threshold (in the case of high-speed movement) When the moving speed of the mobile station 200 is less than the threshold (when moving at a low speed), the CDD mode of transmission data addressed to the mobile station 200 is determined as the SD-CDD mode.

  In the above-described embodiment, a case has been described in the mobile communication system where the transmitting-side radio communication device is a base station and the receiving-side radio communication device is a mobile station. By using the communication apparatus as a mobile station and the receiving-side radio communication apparatus as a base station, the same operations and effects as described above can be achieved.

  Further, although cases have been described with the above embodiment as examples where the present invention is configured by hardware, the present invention can also be realized by software.

  Each functional block used in the description of the above embodiment is typically realized as an LSI which is an integrated circuit. These may be individually made into one chip, or may be made into one chip so as to include a part or all of them. The name used here is LSI, but it may also be called IC, system LSI, super LSI, or ultra LSI depending on the degree of integration.

  Further, the method of circuit integration is not limited to LSI's, and implementation using dedicated circuitry or general purpose processors is also possible. An FPGA (Field Programmable Gate Array) that can be programmed after manufacturing the LSI, or a reconfigurable processor that can reconfigure the connection and setting of circuit cells inside the LSI may be used.

  Further, if integrated circuit technology comes out to replace LSI's as a result of the advancement of semiconductor technology or a derivative other technology, it is naturally also possible to carry out function block integration using this technology. Biotechnology can be applied.

  The disclosure of the specification, drawings, and abstract contained in the Japanese application of Japanese Patent Application No. 2007-161968 filed on June 19, 2007 is incorporated herein by reference.

  The present invention can be applied to a mobile communication system or the like.

  The present invention relates to a radio communication apparatus and a symbol arrangement method.

  In recent years, transmission techniques for realizing high-speed and large-capacity data transmission have been studied, and MIMO (Multi Input Multi Output) transmission techniques using a plurality of antennas have attracted attention. In MIMO transmission, it is possible to increase throughput by providing a plurality of antennas on both the transmission side and the reception side, preparing a plurality of propagation paths in the space between wireless transmission and reception, and spatially multiplexing each propagation path. it can.

  In addition, as a peripheral element technology for MIMO transmission, cyclic delay diversity that increases the selectivity of fading channels by equivalently increasing the number of delay paths by simultaneously transmitting signals with different cyclic delays for each antenna from a plurality of antennas. (CDD: Cyclic Delay Diversity) technology has been studied (for example, see Non-Patent Document 1). CDD has two types of CDD modes: SD-CDD (Small Delay CDD) with a small amount of cyclic delay and LD-CDD (Large Delay CDD) with a large amount of cyclic delay.

  In SD-CDD with a small amount of cyclic delay, fading channel fluctuations are slow over all resource blocks (RB). Therefore, with SD-CDD, a large frequency scheduling gain can be obtained, and the maximum multi-user diversity effect can be obtained. SD-CDD is a method suitable for data communication when a radio communication mobile station apparatus (hereinafter abbreviated as a mobile station) moves at low speed. On the other hand, in the LD-CDD having a large amount of cyclic delay, the fading channel fluctuation increases within 1 RB, so that a large frequency diversity gain can be obtained. LD-CDD is an effective method in situations where frequency scheduling transmission is difficult to apply.

As a peripheral element technology for MIMO transmission, there is a link adaptation technology. The link adaptation technique is a technique for adaptively controlling an MCS (Modulation and Coding Scheme) level indicating a coding rate and a modulation scheme according to the channel quality of a propagation path between transmission and reception. When link adaptation technology is applied to a mobile communication system, each mobile station measures SINR (Signal to Interference and Noise) of a common reference signal, and calculates an average SINR for each RB from the measured SINR. Each mobile station determines the MCS level used by the mobile station using the average SINR for each RB. Each mobile station reports the MCS level to a radio communication base station apparatus (hereinafter abbreviated as a base station). The base station encodes and modulates transmission data based on the MCS level from each mobile station and transmits it to each mobile station.
3GPP RAN WG1 LTE Adhoc meeting (2006.01) R1-060011 “Cyclic Shift Diversity for E-UTRA DL Control Channels & TP”

  As described above, the MCS level used by the mobile station is determined using the average SINR for each RB. Therefore, in order to appropriately use the determined MCS level for the plurality of subcarriers in the RB, it is preferable that all the SINRs of the plurality of subcarriers in the RB are the same as the average SINR. That is, it is preferable that the SINRs of the plurality of subcarriers in the RB are uniform. Therefore, the fading channel (hereinafter referred to as CDD channel) variation due to CDD is constant, and SD-CDD, which can obtain uniform SINR among subcarriers, is an effective method for link adaptation technology.

  However, when the CDD mode of the interference signal from another cell is LD-CDD, the interference power of each subcarrier varies with the CDD fluctuation period of LD-CDD. Therefore, when a desired signal is transmitted by SD-CDD from the base station, the SINR of each subcarrier in the RB fluctuates in the CDD channel fluctuation period of the LD-CDD from another cell in the mobile station. , There is a large difference in SINR between the subcarriers in the RB. Therefore, when the CDD mode of the interference signal from another cell is LD-CDD, appropriate link adaptation cannot be performed.

  Therefore, in the base station, in order to keep the SINR of a plurality of subcarriers in the RB uniform, it is necessary to reduce the influence of CDD channel fluctuations of interference signals from other cells.

  An object of the present invention is to provide a radio communication apparatus and a symbol arrangement method that can reduce the influence of CDD channel fluctuations of interference signals from other cells when CDD is used.

  The wireless communication apparatus of the present invention is a base station that performs cyclic delay diversity transmission of a multicarrier signal composed of a plurality of subcarriers, and in the plurality of subcarriers, a part of the same symbols is converted to LD- Arranged on the first subcarrier located in the peak portion of the channel fluctuation of CDD, and arranged symbols other than the part of the plurality of symbols on the second subcarrier located in the valley portion of the channel fluctuation. An arrangement is provided that includes arrangement means and transmission means for transmitting the multicarrier signal in which the plurality of symbols are arranged on the plurality of subcarriers.

  ADVANTAGE OF THE INVENTION According to this invention, when using CDD, the influence by the CDD channel fluctuation | variation of the interference signal from another cell can be reduced.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the following description, the wireless communication device on the transmission side is a base station, and the wireless communication device on the reception side is a mobile station. In the following description, the CDD mode of a desired signal transmitted from the base station is SD-CDD, and the CDD mode of an interference signal from another cell is LD-CDD.

(Embodiment 1)
The configuration of base station 100 according to the present embodiment is shown in FIG.

  In base station 100 shown in FIG. 1, transmission parameter control section 101, based on feedback information from the mobile station, MCS level (coding rate and modulation scheme), transmission data for transmission data (desired signal) to each mobile station. It controls the repetition factor (RF) and the CDD mode (SD-CDD or LD-CDD) of transmission data to each mobile station. Here, the feedback information from the mobile station includes the MCS level determined based on the SINR of the received signal of the mobile station, the CDD mode of transmission data to the mobile station, and the CDD mode of interference signals from other cells. . When the CDD mode of the interference signal from another cell is LD-CDD, transmission parameter control section 101 determines RF based on the number of cyclic delay shift samples of LD-CDD, that is, the CDD channel fluctuation period of LD-CDD. To do. In addition, the transmission parameter control unit 101 changes the MCS level to increase in accordance with the determined RF in order to prevent a decrease in data rate due to repetition. On the other hand, when the CDD mode of the interference signal from another cell is SD-CDD, the transmission parameter control unit 101 does not determine the RF and change the MCS level. Then, the transmission parameter control unit 101 generates a control signal indicating the MCS level after control, the determined RF, and the CDD mode of transmission data to the mobile station. Then, transmission parameter control section 101 outputs the controlled MCS level to encoding section 102 and modulation section 103, outputs the determined RF to repetition section 104, outputs the control signal to arrangement section 105, and moves it. The CDD mode of transmission data to the station is output to cyclic delay section 106-1 and cyclic delay section 106-2. Details of the control processing in the transmission parameter control unit 101 will be described later.

  Encoding section 102 encodes transmission data according to the coding rate input from transmission parameter control section 101. Then, encoding section 102 outputs the encoded transmission data to modulating section 103.

  Modulation section 103 modulates the encoded transmission data input from encoding section 102 according to the modulation scheme input from transmission parameter control section 101 to generate data symbols. Modulation section 103 then outputs the generated data symbol to repetition section 104.

  The repetition unit 104 repeats the data symbol input from the modulation unit 103 according to the RF input from the transmission parameter control unit 101. For example, when RF = 2, the repetition unit 104 repeats the data symbol to obtain the same two symbols. Then, repetition section 104 outputs the same plurality of symbols including data symbols and repetition symbols to arrangement section 105.

  Arrangement section 105 multiplexes the common reference signal, the control signal input from transmission parameter control section 101, and the same plurality of symbols input from repetition section 104, and also combines the multiplexed signal into a plurality of sub-signals. Place each on the carrier. At this time, arrangement section 105 arranges some of the same symbols on subcarriers located at the peak of the CDD channel fluctuation of LD-CDD, and arranges symbols other than the some of the symbols. It arrange | positions to the subcarrier located in the valley part of the CDD channel fluctuation | variation of LD-CDD. Arrangement unit 105 then outputs the multiplexed signal to cyclic delay unit 106-1 and cyclic delay unit 106-2. Details of the arrangement processing in the arrangement unit 105 will be described later.

  Cyclic delay section 106-1, IFFT (Inverse Fast Fourier Transform) section 107-1, CP adding section 108-1 and radio transmitting section 109-1 are provided corresponding to antenna 110-1. Further, cyclic delay section 106-2, IFFT section 107-2, CP adding section 108-2 and radio transmitting section 109-2 are provided corresponding to antenna 110-2.

  Cyclic delay unit 106-1 and cyclic delay unit 106-2, for each symbol arranged in a plurality of subcarriers among the multiplexed signals input from arrangement unit 105, are transmitted from transmission parameter control unit 101. Different cyclic delays are given according to the input CDD mode. Specifically, since the CDD mode input from transmission parameter control section 101 is SD-CDD, cyclic delay section 106-1 does not give a cyclic delay to each symbol, and cyclic delay section 106-2 , A cyclic delay of the number of SD-CDD cyclic delay shift samples is given to each symbol. Then, cyclic delay section 106-1 and cyclic delay section 106-2 output the signal after the cyclic delay to IFFT section 107-1 and IFFT section 107-2, respectively.

  IFFT section 107-1 and IFFT section 107-2 perform IFFT processing on the subcarriers on which the signals after cyclic delay input from cyclic delay section 106-1 and cyclic delay section 106-2 are arranged, respectively. The frequency domain signal is converted to a time domain signal to generate an OFDM symbol. Then, IFFT section 107-1 and IFFT section 107-2 output the OFDM symbols to CP adding section 108-1 and CP adding section 108-2, respectively.

  CP adding section 108-1 and CP adding section 108-2 add the same signal as the tail part of each OFDM symbol to the beginning of each OFDM symbol as a CP. Then, CP adding section 108-1 and CP adding section 108-2 output the OFDM symbols after the CP addition to radio transmitting section 109-1 and radio transmitting section 109-2, respectively.

  Radio transmitting sections 109-1 and 109-2 perform transmission processing such as D / A conversion, amplification and up-conversion on the OFDM symbol after CP addition, and transmit the OFDM symbol after transmission processing to antennas 110-1 and 110-2. -2 at the same time. Thereby, a plurality of OFDM symbols are CDD transmitted from a plurality of antennas.

  Next, details of the control processing in the transmission parameter control unit 101 will be described.

  Transmission parameter control section 101 determines RF based on the number of LD-CDD cyclic delay shift samples of interference signals from other cells. Specifically, transmission parameter control section 101 sets RF as the number of subcarriers corresponding to a frequency interval for one period of CDD channel fluctuation of LD-CDD. For example, when the number of cyclic delay shift samples is N / 2, the number of subcarriers corresponding to the frequency interval for one period of the CDD channel fluctuation of LD-CDD is 2, so the transmission parameter control unit 101 sets RF to 2 decide. Similarly, transmission parameter control section 101, when the number of cyclic delay shift samples is N / 4 (that is, when the number of subcarriers corresponding to the frequency interval for one period of CDD channel fluctuation of LD-CDD is 4), When RF is determined to be 4 and the number of cyclic delay shift samples is N / 8 (that is, when the number of subcarriers corresponding to the frequency interval of one period of CDD channel fluctuation of LD-CDD is 8), RF is set to 8 To decide. Here, N is the number of FFT (Fast Fourier Transform) points. Further, when the CDD mode of the interference signal from another cell is SD-CDD, the transmission parameter control unit 101 does not set the RF.

  Next, transmission parameter control section 101 increases the MCS level included in the feedback information according to the determined RF, that is, the number of subcarriers corresponding to the frequency interval for one period of LDD-CDD CDD channel fluctuation. Here, when the transmission data is repeated at RF = 2, two identical symbols are obtained, so that the data rate is reduced to ½. Therefore, the transmission parameter control unit 101 prevents the data rate from being lowered during data transmission by changing the MCS level to double the data rate.

  For example, as shown in FIG. 2, when the RF determined by the transmission parameter control unit 101 is 2, and the MCS level included in the feedback information is R = 1/3, QPSK, the transmission parameter control unit 101 The conversion rate is changed to 2/3, or the modulation method is changed to 16QAM. That is, the transmission parameter control unit 101 changes the MCS level to R = 2/3, QPSK, or R = 1/3, 16QAM. Here, the data rate in the case of R = 2/3 and QPSK and the data rate in the case of R = 1/3 and 16QAM are both twice the data rate in the case of R = 1/3 and QPSK. As described above, when the transmission data is repeated at RF = 2, the data rate is changed to the MCS level that is doubled, so that it is possible to prevent the data rate from being lowered during data transmission. As shown in FIG. 2, the transmission parameter control unit 101 may change either the coding rate or the modulation scheme when increasing the MCS level according to RF. Both may be changed.

  Next, the parameter change processing flow of the transmission parameter control unit 101 will be described with reference to the flowchart of FIG.

  In ST (step) 101, transmission parameter control section 101, when the CDD mode (other cell CDD mode) of the interference signal from another cell is LD-CDD (ST101: YES), from ST102, RF is determined based on the number of cyclic delay shift samples of LD-CDD of the interference signal.

  In ST103, transmission parameter control section 101 changes the MCS level based on the RF determined in ST102.

  On the other hand, when the CDD mode of the interference signal from another cell is SD-CDD (ST101: NO), transmission parameter control section 101 does not perform repetition on the data symbol in base station 100, so nothing is done. The process ends without doing.

  Next, details of the data symbol arrangement processing in arrangement section 105 will be described. Here, RF determined by transmission parameter control section 101 is set to 2, and the number of cyclic delay shift samples of LD-CDD of interference signals from other cells is set to N / 2.

FIG. 4 shows an RB composed of ₁₂ subcarriers f _{1 to} f ₁₂ . Here, since RF is 2, as shown in FIG. 4, as shown in FIG. 4, data symbols S <b> 1 to S <b> 6 and repetition symbols S <b> 1 ′ to S <b> 6 ′ generated by repetition of data symbols S <b> 1 to S <b> 6. Are input from the repetition unit 104. Here, S1 to S6 and S1 ′ to S6 ′ are the same symbols.

Further, since the number of cyclic delay shift samples of LD-CDD of interference signals from other cells is N / 2, as shown in FIG. The number of subcarriers for one period (variation in interference power) is 2. In other words, the frequency interval between the subcarriers in subcarriers f _{1 to} f ₁₂ is a half period of CDD channel fluctuation of LD-CDD of interference signals from other cells. That is, the CDD channels of LD-CDD in adjacent subcarriers have opposite phases. For example, as shown in FIG. 4, _{f 1} is LD-CDD of located on a mountain portion (high interference power) of the CDD channel fluctuation, _{f 2} adjacent to _{f 1} valley portion of the CDD channel fluctuation of LD-CDD ( (Small interference power).

  Therefore, arranging section 105 places the same plurality of symbols in sub-carriers located in the peak portion (large interference power) of CDD channel fluctuation of LD-CDD and in the valley portion (small interference power) of CDD channel fluctuation of LD-CDD. It arrange | positions equally to the subcarrier located. Here, since RF = 2, allocating section 105 uses the same two symbols as the subcarriers located at the peak portion (large interference power) of CDD channel fluctuation of LD-CDD and the CDD channel fluctuation of LD-CDD. One for each subcarrier located in the valley portion (small interference power).

Specifically, as shown in FIG. 4, placement section 105 places S1 on f ₁ (the peak portion of the CDD channel fluctuation of LD-CDD) and S1 ′ on f ₂ (the CDD channel of LD-CDD). Place in the valley of fluctuation). That is, S1 and S1 ′ are respectively arranged in f ₁ and f ₂ that are in opposite phases in the CDD channel of the LD-CDD. Similarly, placement section 105 places S2 at f ₃ (the peak portion of the CDD channel fluctuation of LD-CDD) and S2 ′ at f ₄ (the valley portion of the CDD channel fluctuation of LD-CDD). The same applies to S3 to S6 and S3 ′ to S6 ′.

  As described above, the same plurality of symbols include a peak portion of the CDD channel fluctuation of LD-CDD (large interference power), that is, a subcarrier having poor channel quality (low SINR) and a CDD channel fluctuation of LD-CDD. It is distributed and arranged in valley portions (small interference power), that is, subcarriers with good channel quality (high SINR). In other words, since the same plurality of symbols are uniformly distributed over a plurality of subcarriers corresponding to a frequency interval of one period of CDD channel fluctuation of LD-CDD, a diversity effect can be obtained. Thereby, the interference power from other cells is averaged in a plurality of subcarriers in the RB in which the data symbols are arranged, and the interference power can be made uniform.

  Next, FIG. 5 shows the configuration of mobile station 200 according to the present embodiment.

  In mobile station 200 shown in FIG. 5, radio receiving section 202-1, CP removing section 203-1 and FFT section 204-1 are provided corresponding to antenna 201-1. Radio reception section 202-2, CP removal section 203-2, and FFT section 204-2 are provided corresponding to antenna 201-2.

  Radio receiving section 202-1 and radio receiving section 202-2 receive OFDM symbols, which are multicarrier signals that are CDD transmitted from base station 100 (FIG. 1), via antenna 201-1 and antenna 201-2, respectively. The OFDM symbol is subjected to reception processing such as down-conversion and A / D conversion. Then, radio reception section 202-1 and radio reception section 202-2 output the OFDM symbols after radio reception processing to CP removal section 203-1 and CP removal section 203-2, respectively. The OFDM symbol includes a plurality of identical symbols including a data symbol and a repetition symbol, a common reference signal, and a control signal. Further, this OFDM symbol is interfered by a signal from another cell in the propagation path.

  CP removing section 203-1 and CP removing section 203-2 remove the CP from the OFDM symbols input from radio receiving section 202-1 and radio receiving section 202-2, respectively. Then, CP removal section 203-1 and CP removal section 203-2 output the OFDM symbols after CP removal to FFT section 204-1 and FFT section 204-2, respectively.

  FFT section 204-1 and FFT section 204-2 perform FFT processing on the OFDM symbols respectively input from CP removal section 203-1 and CP removal section 203-2, and convert the time domain signal to the frequency domain signal. Convert to Then, FFT section 204-1 and FFT section 204-2 output the signal after the FFT to separation section 205.

  Separating section 205 separates the signal after FFT input from FFT section 204-1 and FFT section 204-2 into the same plurality of symbols, common reference signal, and control signal. Separating section 205 then outputs the same plurality of symbols to combining section 206, outputs a common reference signal to SINR measuring section 209, and controls signals to combining section 206, demodulating section 207, decoding section 208, and SINR measuring section. To 209.

  The combining unit 206 combines a data symbol and a repetition symbol corresponding to the data symbol among the same plurality of symbols input from the separating unit 205 to generate a combined symbol. Specifically, combining section 206 is arranged in a symbol arranged in a subcarrier located in a peak portion of CDD channel fluctuation of LD-CDD and a subcarrier located in a valley portion of CDD channel fluctuation of LD-CDD. Combining with the symbol. Here, the synthesis unit 206 determines the number of symbols to be synthesized according to the RF indicated by the control signal input from the separation unit 205. Then, combining section 206 outputs the generated combined symbol to demodulation section 207. Details of the composition processing in the composition unit 206 will be described later.

  Demodulating section 207 demodulates the combined symbol input from combining section 206 according to the modulation scheme indicated by the control signal input from separating section 205. Demodulation section 207 then outputs the demodulated data signal to decoding section 208.

  Decoding section 208 decodes the demodulated data signal input from demodulation section 207 according to the coding rate indicated by the control signal input from separation section 205. Decoding section 208 then outputs the decoded data signal as received data.

  On the other hand, the SINR measurement unit 209 measures the SINR of the common reference signal input from the separation unit 205 based on the CDD mode indicated by the control signal input from the separation unit 205. Specifically, the SINR measurement unit 209 gives a cyclic delay in the CDD mode indicated by the control signal to the common reference signal, and measures the SINR of the common reference signal after the cyclic delay. As described above, the SINR measurement unit 209 can reflect the influence of the CDD channel of the data signal on the SINR measurement of the common reference signal by giving the common reference signal the same cyclic delay as that of the data signal. Then, the SINR measurement unit 209 outputs the measured SINR to the transmission parameter determination unit 210.

  Transmission parameter determination section 210 determines the MCS level and the CDD mode of transmission data addressed to the own station based on the SINR input from SINR measurement section 209. For example, the transmission parameter determination unit 210 determines a larger MCS as the SINR is higher. Further, for example, when the SINR is equal to or greater than the threshold, the transmission parameter determination unit 210 determines the CDD mode of the transmission data addressed to the own station to the SD-CDD mode, and when the SINR is less than the threshold, the CDD mode of the transmission data addressed to the own station. To the LD-CDD mode. Then, transmission parameter determination section 210 outputs MCS level, CDD mode of transmission data addressed to its own station, and CDD mode of interference signals from other cells input from a reception section (not shown) to feedback information generation section 211.

  The feedback information generation unit 211 generates feedback information including the MCS level input from the transmission parameter determination unit 210, the CDD mode of transmission data addressed to the own station, and the CDD mode of interference signals from other cells. Then, the feedback information generation unit 211 feeds back the generated feedback information to the base station 100.

  Next, details of the composition processing in the composition unit 206 will be described.

FIG. 6 shows an RB composed of ₁₂ subcarriers f _{1 to} f ₁₂ as in FIG. Here, RF indicated by the control signal is set to 2. Further, as described above, the same symbol is arranged in adjacent subcarriers. Further, in the received signal before symbol synthesis, the frequency interval for one period of the CDD channel fluctuation (interference power) of the LD-CDD of the interference signal from another cell is equivalent to the frequency interval of 2 subcarriers as in FIG. To do. Therefore, the CDD channel fluctuation (interference power) of LD-CDD has an opposite phase between adjacent subcarriers. That is, every other subcarrier, high interference power (the peak portion of the LD-CDD CDD channel fluctuation) and small interference power (the LD-CDD valley portion of the CDD channel fluctuation) appear alternately. Here, as shown in FIG. 6A, the interference power of the interference signal from another cell is large in the odd-numbered subcarrier (the peak portion of the CDD channel fluctuation of LD-CDD), and the even-numbered subcarrier is small. Assume that this is the valley portion of the CDD channel fluctuation of LD-CDD. On the other hand, as shown in FIG. 6A, the reception power of a signal from base station 100 (FIG. 1), that is, the desired power of transmission data transmitted by SD-CDD is constant between subcarriers. Therefore, the SINR in each subcarrier before symbol combination varies according to the variation in interference power from other cells. That is, as shown in FIG. 6B, the SINR of odd-numbered subcarriers is low, and the SINR of even-numbered subcarriers is high.

Since RF = 2, the synthesis unit 206 performs symbol synthesis on the symbols arranged on the adjacent two subcarriers. Specifically, as shown in FIG. 6C, combining section 206 performs data symbols S1 and f ₂ (LD-CDD CDD channel fluctuation fluctuations) arranged at f ₁ (the peak part of LD-CDD CDD channel fluctuations). The repetition symbol S1 ′ arranged in the valley portion) is symbol-synthesized to generate a synthesized symbol S1 ″. Similarly, the synthesis unit 206 is arranged in f ₃ (the peak portion of the CDD channel fluctuation of LD-CDD). S2 ″ is generated by combining symbols S2 and S2 ′ arranged in f ₄ (the valley portion of the CDD channel fluctuation of LD-CDD). The same is true for f ₅ ~f _12.

Here, as shown in FIG. 6C, the received power at f ₁ and f ₂ where S1 ″ is arranged is the received power at f ₁ where S1 is arranged and the received power of f ₂ where S1 ′ is arranged. Therefore, the SINR at f ₁ and f ₂ where S1 ″ is arranged is equal to the average value of the SINR of f _{1 and} the SINR of f ₂ as shown in the SINR characteristics after symbol synthesis in FIG. Become. The same applies to S2 ″ to S6 ″. That is, as shown in FIG. 6D, since the SINRs of the received signals after the symbol synthesis of all subcarriers are averaged, the SINR of each subcarrier of transmission data transmitted by SD-CDD is a CDD channel of LD-CDD. It is possible to prevent fluctuations in the same way as fluctuations.

  As described above, according to the present embodiment, a plurality of identical symbols generated by repetition of transmission data are generated from the peak portion of CDD channel fluctuation (from the own cell) due to LD-CDD of interference signals from other cells. Subcarriers located in the portion where the SINR of the desired signal is low) and subcarriers located in the valley portion of the CDD channel fluctuation due to LD-CDD of the interference signal from other cells (the portion where the SINR of the desired signal from the own cell is high) Distributed to the carrier. Thereby, as described above, the SINRs of all subcarriers in the RB can be made uniform, and can be approximated to the CDD channel of SD-CDD. That is, according to the present embodiment, even when transmission data is transmitted by SD-CDD, it is possible to reduce the influence due to the CDD channel fluctuation of LD-CDD of interference signals from other cells. Thereby, even when transmission data is transmitted by SD-CDD, since the SINR of all subcarriers in the RB can be made uniform in the mobile station, the accuracy of link adaptation performed in units of RBs is improved. Can do.

In the present embodiment, as shown in FIG. 4, data symbols and repetition symbols generated by repetition of the data symbols are arranged on consecutive subcarriers. However, the data symbol and the repetition symbol do not need to be allocated to consecutive subcarriers, respectively, and are allocated to subcarriers located at peak portions and valley portions of LD-CDD CDD channel fluctuations, respectively. It only has to be done. For example, in FIG. 4, a data symbol and a repetition symbol are in any one of subcarriers f ₁ , f ₃ , f ₅ , f ₇ , f ₉ , and f ₁₁ located at the peak portion of the CDD channel fluctuation of LD-CDD. One of the subcarriers f ₂ , f ₄ , f ₆ , f ₈ , f ₁₀ , and f ₁₂ located in the valley portion of the CDD channel fluctuation of the LD-CDD may be arranged. .

(Embodiment 2)
In the first embodiment, the same plurality of data symbols are arranged in either the peak portion or valley portion of the CD-D channel fluctuation of LD-CDD without considering the time. That is, a plurality of identical data symbols are combined at the same time.

  However, if the same plurality of data symbols are arranged on both the subcarrier located in the peak part of the CDD channel fluctuation of LD-CDD and the subcarrier located in the valley part, the same effect as in the first embodiment is obtained. be able to. That is, the same plurality of data symbols may not be arranged on subcarriers at the same time. That is, the same plurality of data symbols may be arranged in both the peak portion and the valley portion of the CDD channel variation of LD-CDD at different times. Therefore, in the present embodiment, the same plurality of data symbols are arranged at different times on the subcarriers located in the peak portion of the LD-CDD CDD channel fluctuation and the subcarriers located in the valley portion.

  First, base station 100 (FIG. 1) according to the present embodiment will be described. In base station 100 according to the present embodiment, description of the same operation as in Embodiment 1 is omitted.

  Transmission parameter control section 101 holds a plurality of subcarrier arrangement patterns for data symbols. Then, the transmission parameter control unit 101 determines one of a plurality of arrangement patterns according to the number of transmission data transmissions. Note that the number of transmissions is the same as the number of RFs determined by the transmission parameter control unit 101. Then, transmission parameter control section 101 outputs the determined arrangement pattern to arrangement section 105.

  The repetition unit 104 outputs the data symbols input from the modulation unit 103 to the placement unit 105 by the same number of transmissions as the RF input from the transmission parameter control unit 101 at different times. The repetition unit 104 may duplicate the data symbols as many times as the number of transmissions to generate the same plurality of data symbols, and output the generated plurality of the same data symbols to the arrangement unit 105 at different times, respectively. The data symbols may be temporarily stored, and the stored data symbols may be output to the arrangement unit 105 at different times. The data symbols are duplicated at each transmission to generate a plurality of identical data symbols. The same plurality of data symbols may be output to the arrangement unit 105 at different times.

  Arrangement section 105 arranges the same plurality of data symbols input at different times from repetition section 104 according to the arrangement pattern input from transmission parameter control section 101 on each subcarrier.

  Next, details of the arrangement processing in the arrangement unit 105 will be described.

FIG. 7 shows an RB composed of ₁₂ subcarriers f _{1 to} f ₁₂ . Here, as in the first embodiment, out of f _{1 to} f ₁₂ , odd-numbered subcarriers are located in the peak portion (large interference power) of the CDD channel fluctuation of LD-CDD of interference signals from other cells. The even-numbered subcarriers are assumed to be located in the valley portion (small interference power) of the CDD channel fluctuation of the LD-CDD of the interference signal from another cell. In addition, data symbols S <b> 1 to S <b> 12 are input to the placement unit 105 from the repetition unit 104 at different times. Also, RF is 2. That is, S1 to S12 are input to the placement unit 105 twice.

  Arrangement section 105 arranges data symbols arranged in subcarriers located in the peak portion of CDD channel fluctuation of LD-CDD (valley portion of CDD channel fluctuation of LD-CDD) in the first transmission into LD in the second transmission. -It arrange | positions to the subcarrier located in the valley part (CDD channel fluctuation peak part of LD-CDD) of the CDD channel fluctuation of CDD.

Specifically, arranging section 105, in the first transmission, as shown in FIG. _7, placing the S1~S12 to f 1 _{~f 12} respectively. That, S1, S3, S5, S7 , S9, S11 is the _{f 1, f 3, f 5} , f 7, f 9, f 11 is located in the mountain portion (high interference power) of the CDD channel fluctuation of LD-CDD F ₂ , f ₄ , f ₆ , f ₈ , f ₁₀ where S 2, S 4, S 6, S 8, S 10, S 12 are located in the valley part (small interference power) of the CDD channel fluctuation of LD-CDD. , respectively disposed _{f 12.}

Then, in the second transmission, as shown in FIG. 7, arrangement section 105 has S2, S4, S6, S8, S10, and S12 located at the peak portion (large interference power) of CDD channel fluctuation of LD-CDD. f ₁ , f ₃ , f ₅ , f ₇ , f ₉ , and f ₁₁ are arranged respectively, and S 1, S 3, S 5, S 7, S 9, and S 11 are valley portions of CDD channel fluctuations of LD-CDD (small interference power) ) Located at f ₂ , f ₄ , f ₆ , f ₈ , f ₁₀ , and f ₁₂ .

  Thus, at different times (at the time of the first transmission and at the time of the second transmission), the same plurality of data symbols are arranged in the peak and valley portions of the LD-CDD CDD channel fluctuation as in the first embodiment. can do.

  Next, mobile station 200 (FIG. 5) according to the present embodiment will be described. In mobile station 200 according to the present embodiment, description of the same operation as in Embodiment 1 is omitted.

  When receiving the first transmission data, combining section 206 stores the data symbol input from demultiplexing section 205 and outputs it as it is to demodulation section 207. On the other hand, at the time of receiving the second transmission data, the combining unit 206 generates a combined symbol by combining the data symbol input from the separating unit 205 and the stored data symbol, and stores the generated combined symbol. Output to demodulator 207. Here, the combining unit 206 holds the same arrangement pattern as the plurality of arrangement patterns held by the transmission parameter control unit 101 of the base station 100 (FIG. 1). Further, the synthesis unit 206 determines the arrangement pattern to be used in the plurality of arrangement patterns based on the RF indicated in the control information input from the separation unit 205.

  Next, details of the composition processing in the composition unit 206 will be described.

FIG. 8 shows an RB composed of ₁₂ subcarriers f _{1 to} f ₁₂ as in FIG. Here, every other subcarrier, high interference power (the peak portion of LD-CDD CDD channel fluctuation) and small interference power (the LD-CDD valley portion of CDD channel fluctuation) appear alternately. Further, when receiving the first transmission data, that is, the first transmission data shown in FIG. 7, the subcarrier f located at the peak portion (large interference power) of the CDD channel fluctuation of LD-CDD as shown in FIG. 8A. ₁ , f ₃ , f ₅ , f ₇ , f _9, f ₁₁ , data symbols S 1, S 3, S 5, S 7, S 9, S 11 are arranged in the valley portion (small interference power) of the CDD channel fluctuation of LD-CDD. subcarriers _{f 2,} f ₄ which is _{located, f 6, f 8, f} 10, f 12 in S2, S4, S6, S8, S10, S12 are arranged. That is, as shown in FIG. 8B, the SINR of odd-numbered subcarriers is low, and the SINR of even-numbered subcarriers is high.

Further, when receiving the second transmission data, that is, the second transmission data shown in FIG. 7, the subcarrier f located at the peak portion (large interference power) of the CDD channel fluctuation of LD-CDD as shown in FIG. 8C. ₁ , f ₃ , f ₅ , f ₇ , f _9, f ₁₁ are arranged S 2, S 4, S 6, S 8, S 10, S 12, and located in the valley portion (small interference power) of CDD channel fluctuation of LD-CDD. subcarriers _{f 2, f 4, f 6} , f 8, f 10, f 12 in S1, S3, S5, S7, S9, S11 are arranged. That is, as shown in FIG. 8D, the SINR of odd-numbered subcarriers is low, and the SINR of even-numbered subcarriers is high.

Combining section 206 receives the data symbol arranged on the subcarrier located at the peak portion of the LD-CDD CDD channel fluctuation (the valley portion of the LD-CDD CDD channel fluctuation) at the time of receiving the first transmission data, and the second time At the time of reception of transmission data, the data symbols arranged on the subcarriers located in the valley part of the CDD channel fluctuation of LD-CDD (the peak part of CDD channel fluctuation of LD-CDD) are combined. Specifically, as illustrated in FIG. 8E, the combining unit 206 includes S1 arranged in f _{1 of the} first transmission data (the peak portion of the CDD channel fluctuation of LD-CDD) and f _{2 of the} second transmission data ( S1 arranged in the valley portion of the CDD channel fluctuation of LD-CDD) is combined to generate a combined symbol S1 ′. Similarly, combining section 206 has S2 arranged in f _{2 of the} first transmission data (the valley portion of the CDD channel fluctuation of LD-CDD) and f _{1 of the} second transmission data (the peak of the CDD channel fluctuation of LD-CDD). S2 arranged in (part) is synthesized to generate a synthesized symbol S2 ′. The same applies to the S3~S12 disposed f ₃ ~f _12. As a result, the synthesis unit 206 generates synthesized symbols S1 ′ to S12 ′.

  That is, combining section 206 has subcarriers located at the peak of the CDD channel fluctuation of LD-CDD in the first transmission data (second transmission data), that is, data symbols arranged on subcarriers with low SINR, and 2 In the first transmission data (first transmission data), subcarriers located in valley portions of the CDD channel fluctuation of LD-CDD, that is, data symbols arranged on subcarriers having a high SINR are combined. Thereby, combining section 206 can supplement the SINR of the data symbol having a low SINR in the first transmission data (second transmission data) with the second transmission data. Therefore, since the SINRs between the combined symbols obtained in the mobile station are averaged to the same level, similarly to Embodiment 1, the influence of the CD-D channel variation of LD-CDD on the transmission data transmitted by SD-CDD Can be reduced.

  Thus, the same effect as in the first embodiment can be obtained even if the same data symbols are arranged in the peak and valley portions of the CD-D channel fluctuation of LD-CDD at different times.

  As a technique for transmitting the same data at different times, there is a CC (Chase Combining) type HARQ (Hybrid Automatic Repeat reQuest). In CC-type HARQ, the mobile station feeds back an ACK (Acknowledgment) signal to the base station as a response signal when there is no error in the received data and a NACK (Negative Acknowledgment) signal when there is an error. When receiving the NACK signal, the base station retransmits all of the transmission data. Then, the mobile station combines the data retransmitted from the base station and the data with errors received in the past, and performs error correction decoding on the combined data.

  Then, next, the case where this Embodiment is applied to CC system HARQ is demonstrated as an example.

  First, the base station according to this example will be described. FIG. 9 shows the configuration of base station 300 according to this example. In FIG. 9, the same components as those shown in FIG. Further, the description of the same operation as that described above is also omitted.

  In base station 300 shown in FIG. 9, transmission parameter control section 101 calculates the number of retransmissions from the response signal included in the feedback information, and determines the subcarrier arrangement pattern for the data symbol based on the number of retransmissions. Then, transmission parameter control section 101 outputs the determined arrangement pattern to arrangement section 105. Also, the transmission parameter control unit 101 outputs a response signal to the HARQ unit 301.

  HARQ section 301 stores the data symbol input from modulation section 103 and outputs the data symbol to arrangement section 105 according to the response signal input from transmission parameter control section 101. Specifically, HARQ section 301 outputs a data symbol to arrangement section 105 in the first transmission (initial transmission). HARQ section 301 outputs the stored data symbol to arrangement section 105 when a NACK signal is input from transmission parameter control section 101, that is, in the second transmission (first retransmission). Further, when an ACK signal is input from transmission parameter control section 101, HARQ section 301 stops outputting data symbols to arrangement section 105 and discards the stored data symbols.

  Next, the mobile station according to this example will be described. FIG. 10 shows the configuration of the mobile station 400 according to this example. In FIG. 10, the same components as those shown in FIG. Further, the description of the same operation as that described above is also omitted.

  In mobile station 400 shown in FIG. 10, combining section 401 stores the data symbol input from demultiplexing section 205 and outputs it to demodulation section 207 as it is when receiving the first transmission data (initial transmission data). On the other hand, when receiving the second transmission data (first retransmission data), that is, when a NACK signal is input from an error detection unit 402 described later, the combining unit 401 receives data input from the separation unit 205. The symbol and the stored data symbol are combined to generate a combined symbol, and the generated combined symbol is stored and output to the demodulation unit 207. Further, when the ACK signal is input from the error detection unit 402, the synthesis unit 401 discards the stored data symbol.

  The error detection unit 402 performs error detection on the decoded data signal input from the decoding unit 208. If there is an error in the decoded data signal as a result of error detection, error detection section 402 generates a NACK signal as a response signal and outputs it to combining section 401 and feedback information generation section 211. If there is no error, an ACK signal is generated as a response signal and output to the combining unit 401 and the feedback information generating unit 211. In addition, error detection section 402 outputs the decoded data signal as received data when there is no error in the decoded data signal.

  The feedback information generation unit 211 uses the response signal input from the error detection unit 402 to generate feedback information.

  In the present embodiment, the base station transmits the same plurality of data symbols at different times with the number of RF transmissions. On the other hand, in CC-based HARQ, the base station transmits the same data symbol at different times when a NACK signal is fed back as a response signal, that is, when retransmission processing occurs. That is, in the CC-type HARQ, the same effect as in the present embodiment can be obtained when retransmission processing occurs.

  However, in the HARQ of the CC scheme, the retransmission process may be completed with the same number of RFs, that is, the number of retransmissions less than the number of subcarriers corresponding to the frequency interval for one period of CDD channel fluctuation of LD-CDD. That is, in the CC scheme HARQ, it may be impossible to arrange the same data symbol on all subcarriers among subcarriers corresponding to the frequency interval for one period of CDD channel fluctuation of LD-CDD.

  Therefore, at the time of the second transmission (at the time of the first retransmission), placement section 105 has a subcarrier corresponding to a frequency interval corresponding to a half cycle of the CDD channel fluctuation period of LD-CDD at the time of the first transmission (at the first transmission). Data symbols arranged apart from each other are exchanged with each other. Here, the interference powers in the subcarriers separated by a half period of the CDD channel fluctuation period of LD-CDD are in an opposite phase relationship. By combining the data symbol arranged on the subcarrier at the first transmission (at the first transmission) and the data symbol arranged on the subcarrier at the second transmission (at the first retransmission), LD− Of the subcarriers corresponding to the frequency interval for one period of CDD channel fluctuation of CDD, the SINR of two subcarriers can be averaged reliably.

For example, in the case of RF = 2, that is, when the number of subcarriers corresponding to the frequency interval for one period of CDD channel fluctuation of LD-CDD is 2, the arrangement unit 105 performs the first transmission shown in FIG. Data symbols separated by one subcarrier, that is, data symbols arranged on adjacent subcarriers are exchanged with each other. Specifically, the arrangement unit 105, interchanging the S2, which are arranged in _{f 2} adjacent to S1 and _{f 1} which are located in _{f 1,} to place the _{f 1} to S2, placing the _{f 2} to S1. Similarly, arranging section 105, switches the S4, disposed _{f 4} adjacent to S3 and the _{f 3} disposed _{f 3,} arranged _{f 3} to S4, placing the _{f 4} to S3. The same applies to the S5~S12 disposed f ₅ ~f _12. Thus, the arrangement pattern at the second transmission (at the first retransmission) is the same as the arrangement pattern at the second transmission shown in FIG. That is, the symbol composition shown in FIG. 8 can be performed.

  In this way, at the time of retransmission, data symbols are arranged on subcarriers corresponding to the reverse phase of the CDD channel fluctuation of LD-CDD with respect to the subcarriers arranged at the first transmission (at the first transmission). As a result, even when a data symbol is arranged on the subcarrier with the worst SINR at the first transmission, the data symbol can be arranged on the subcarrier with the best SINR at the second transmission (at the first retransmission). it can. Therefore, even when the number of retransmissions is smaller than RF, it is possible to obtain the maximum effect of reducing the influence due to the CDD channel fluctuation of LD-CDD.

  In this example, the case where the number of cyclic delay shift samples is N / 2 has been described as shown in FIG. However, when the number of cyclic delay shift samples is N / 3, that is, when the number of subcarriers corresponding to the frequency interval for one period of the CDD channel fluctuation of LD-CDD is 3, as shown in FIG. At the time of transmission (at the time of the first retransmission), data symbols separated by two subcarriers are exchanged. Also, when the number of cyclic delay shift samples is N / 4, that is, when the number of subcarriers corresponding to the frequency interval for one period of CDD channel fluctuation of LD-CDD is 4, the second transmission (the first retransmission) ), The data symbols separated by 3 subcarriers are exchanged as shown in FIG. 11B.

  Further, in this example, the description has been made up to the second transmission (first retransmission). However, even after the third transmission, it is possible to return to the arrangement pattern at the first transmission again and use the arrangement pattern at the first transmission and the arrangement pattern at the second transmission alternately.

  The case where the present embodiment is applied to CC-type HARQ has been described above.

  Thus, according to the present embodiment, in the transmission data, the base station transmits data symbols arranged in subcarriers having low SINR (high SINR) in the first transmission to high SINR (low in the second transmission). SINR) subcarriers. As a result, the mobile station can improve the SINR of the data symbols arranged in the low SINR subcarriers when receiving the first transmission data when receiving the second transmission data. For this reason, the SINRs of the entire data symbols can be averaged to be uniform. That is, according to the present embodiment, similarly to Embodiment 1, even when CDD is used, it is possible to reduce the influence of CDD channel fluctuations of interference signals from other cells.

  In the present embodiment, for example, as shown in FIGS. 12A, 12B, and 12C, an arrangement pattern in which data symbols are shifted by one subcarrier for each transmission count may be used. Specifically, with respect to the arrangement pattern of the data symbols at the first transmission shown in FIG. 7, the arrangement pattern at the second transmission shifts the data symbols by one subcarrier as shown in FIG. 12A. In the arrangement pattern at the time of transmission, as shown in FIG. 12B, the data symbol is shifted by 2 subcarriers, and in the arrangement pattern at the time of the fourth transmission, the data symbol is shifted by 3 subcarriers as shown in FIG. 12C. As a result, when data symbols are transmitted as many times as the number of transmissions as RF, data symbols are arranged on all subcarriers of a plurality of subcarriers corresponding to the frequency interval for one period of CDD channel fluctuation of LD-CDD. The same actions and effects as described above can be achieved.

  Also, when the present embodiment is applied to CC-type HARQ, the arrangement pattern shown in FIGS. 12A, 12B, and 12C may be used. Specifically, the number of cyclic delay shift samples of LD-CDD at the second transmission (at the first retransmission) with respect to the data symbol arrangement pattern at the first transmission (at the first transmission) shown in FIG. Is N / 2, the arrangement pattern shown in FIG. 12A is used, and when the number of LD-CDD cyclic delay shift samples is N / 3, the arrangement pattern shown in FIG. When the number of samples is N / 4, the arrangement pattern shown in FIG. 12C may be used.

  Furthermore, when this embodiment is applied to CC-type HARQ, the arrangement patterns shown in FIGS. 12A, 12B, and 12C may be used according to the number of retransmissions. Specifically, when the number of cyclic delay shift samples of LD-CDD is N / 2 with respect to the data symbol arrangement pattern at the first transmission (first transmission) shown in FIG. 7, at the second transmission (1 In the second retransmission), the arrangement pattern shown in FIG. 12A is used. When the number of cyclic delay shift samples in LD-CDD is N / 3, the arrangement pattern shown in FIG. 12B is used at the third transmission (at the second retransmission) in addition to the arrangement pattern at the first and second transmissions. . When the number of cyclic delay shift samples of LD-CDD is N / 4, in addition to the arrangement pattern at the time of the first to third transmissions, at the time of the fourth transmission (at the time of the third retransmission), the arrangement pattern shown in FIG. Is used. Thereby, as the number of retransmissions increases, the number of subcarriers in which the same data symbol is arranged increases, and transmissions corresponding to a plurality of subcarriers corresponding to a frequency interval for one period of CDD channel fluctuation of LD-CDD. The same effect as this embodiment can be obtained by the number of times.

  The embodiments of the present invention have been described above.

  In the above embodiment, the receiving unit (not shown) of the mobile station receives the CDD mode of the interference signal from another cell and feeds it back to the base station. However, in the present invention, the CDD mode of the interference signal from another cell is determined at each mobile station using the received signal, and the determined CDD mode of the interference signal from the other cell is fed back to the base station. May be. Moreover, you may notify between base stations via a radio network controller (RNC: Radio Network Controller), without feeding back to a base station via a mobile station.

  CDD may be referred to as CSD (Cyclic Shift Diversity). The CP is sometimes referred to as a guard interval (GI). In addition, the subcarrier may be referred to as a tone. Further, the base station may be represented as Node B, and the mobile station may be represented as UE.

  In the above embodiment, SINR is estimated as channel quality, but SNR, SIR, CINR, CNR, CIR, received power, interference power, bit error rate, packet error rate, throughput, and predetermined error rate can be achieved. You may estimate MCS, the moving speed of a mobile station, delay spread, etc. as channel quality.

  For example, when estimating the moving speed of the mobile station as the channel quality, the mobile station 200 (FIG. 5) includes a moving speed measuring unit instead of the SINR measuring unit 209, and the moving speed measuring unit measures the moving speed of the mobile station 200. To do. Then, transmission parameter determining section 210 (FIG. 5) of mobile station 200 determines that the CDD mode of transmission data addressed to the mobile station 200 is the LD-CDD mode when the moving speed of mobile station 200 is equal to or higher than the threshold (in the case of high-speed movement) When the moving speed of the mobile station 200 is less than the threshold (when moving at a low speed), the CDD mode of transmission data addressed to the mobile station 200 is determined as the SD-CDD mode.

  In the above-described embodiment, a case has been described in the mobile communication system where the transmitting-side radio communication device is a base station and the receiving-side radio communication device is a mobile station. By using the communication apparatus as a mobile station and the receiving-side radio communication apparatus as a base station, the same operations and effects as described above can be achieved.

  Further, although cases have been described with the above embodiment as examples where the present invention is configured by hardware, the present invention can also be realized by software.

  Each functional block used in the description of the above embodiment is typically realized as an LSI which is an integrated circuit. These may be individually made into one chip, or may be made into one chip so as to include a part or all of them. The name used here is LSI, but it may also be called IC, system LSI, super LSI, or ultra LSI depending on the degree of integration.

  Further, the method of circuit integration is not limited to LSI's, and implementation using dedicated circuitry or general purpose processors is also possible. An FPGA (Field Programmable Gate Array) that can be programmed after manufacturing the LSI, or a reconfigurable processor that can reconfigure the connection and setting of circuit cells inside the LSI may be used.

  Further, if integrated circuit technology comes out to replace LSI's as a result of the advancement of semiconductor technology or a derivative other technology, it is naturally also possible to carry out function block integration using this technology. Biotechnology can be applied.

  The disclosure of the specification, drawings, and abstract contained in the Japanese application of Japanese Patent Application No. 2007-161968 filed on June 19, 2007 is incorporated herein by reference.

  The present invention can be applied to a mobile communication system or the like.

Block configuration diagram of a base station according to Embodiment 1 of the present invention The figure which shows the example of a change of MCS which concerns on Embodiment 1 of this invention. The figure which shows the processing flow of the transmission parameter control part which concerns on Embodiment 1 of this invention. The figure which shows the symbol arrangement | positioning which concerns on Embodiment 1 of this invention. Block configuration diagram of a mobile station according to Embodiment 1 of the present invention The figure which shows the symbol synthetic | combination process which concerns on Embodiment 1 of this invention. The figure which shows the symbol arrangement | positioning which concerns on Embodiment 2 of this invention. The figure which shows the symbol arrangement | positioning which concerns on Embodiment 2 of this invention. The block block diagram of the base station which concerns on Embodiment 2 of this invention Block configuration diagram of a mobile station according to Embodiment 2 of the present invention The figure which shows the symbol arrangement | positioning which concerns on Embodiment 2 of this invention (arrangement example 1: number N of cyclic delay shift samples) The figure which shows the symbol arrangement | positioning which concerns on Embodiment 2 of this invention (arrangement example 1: number N of cyclic delay shift samples) The figure which shows the symbol arrangement | positioning which concerns on Embodiment 2 of this invention (arrangement example 2: at the time of the 2nd transmission) The figure which shows the symbol arrangement | positioning which concerns on Embodiment 2 of this invention (arrangement example 2: at the time of the 3rd transmission) The figure which shows the symbol arrangement | positioning which concerns on Embodiment 2 of this invention (arrangement example 2: at the time of the 4th transmission)

Claims (7)

A wireless communication device on the transmission side that transmits cyclic delay diversity transmission of a multicarrier signal composed of a plurality of subcarriers,
In the plurality of subcarriers, a part of the same plurality of symbols is arranged on a first subcarrier located in a peak portion of LD-CDD channel fluctuation, and the part of the plurality of symbols is part of the plurality of symbols. Arranging means for arranging a symbol other than a symbol on a second subcarrier located in a valley portion of the channel variation;
Transmitting means for transmitting the multicarrier signal in which the plurality of symbols are arranged on the plurality of subcarriers;
A wireless communication apparatus on the transmission side comprising: The arranging means arranges the part of the plurality of symbols on the first subcarrier having good quality, and places the symbols other than the part of the plurality of symbols in bad quality on the first subcarrier. Placed on 2 subcarriers,
The wireless communication apparatus according to claim 1. The arrangement means arranges the plurality of symbols equally on the first subcarrier and the second subcarrier.
The wireless communication apparatus according to claim 1. Control means for obtaining the number of subcarriers corresponding to the frequency interval for one period of the channel fluctuation,
The arrangement means arranges the same number of symbols as the number of subcarriers on the plurality of subcarriers.
The wireless communication apparatus according to claim 1. The control means changes MCS of the plurality of symbols according to the number of subcarriers.
The wireless communication apparatus according to claim 4. Receiving means for receiving a multi-carrier signal transmitted by cyclic delay diversity;
In a plurality of subcarriers constituting the multicarrier signal, a symbol arranged in a subcarrier located in a peak portion of LD-CDD channel fluctuation and a symbol arranged in a subcarrier located in a valley portion of the channel fluctuation A synthesis means for synthesizing
A wireless communication device on the receiving side. A symbol arrangement method in a wireless communication apparatus for cyclic delay diversity transmission of a multicarrier signal composed of a plurality of subcarriers,
In the plurality of subcarriers, a part of the same plurality of symbols is arranged on a subcarrier located at a peak portion of LD-CDD channel fluctuation and other than the part of the plurality of symbols. Are arranged on subcarriers located in the valley portion of the channel fluctuation,
Symbol placement method.

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